2013
Mathematical Physical Sciences
Director ate For
&
The NSF Directorate for Mathematical and Physical Sciences consists of the Divisions of
Astronomical Sciences, Chemistry, Materials Research, Mathematical Sciences, and Physics,
as well as the Office of Multidisciplinary Activities. These organizations constitute the
basic structure for MPS support of research and education. The MPS Divisions support
both disciplinary and interdisciplinary activities, and they partner with each other and
with other NSF Directorates in order to effectively encourage basic research across the
scientific disciplines.
Director ate For
Mathematical & Physical Sciences
Division of Astronomical
Sciences
Division of Chemistry
Division of Materials Research
Division of Mathematical
Sciences
Division of Physics
MPS MISSION STATEMENT
The mission of MPS is to harness the collective efforts of the mathematical and physical sciences
communities to address the most compelling scientific questions, educate the future advanced
workforce, and promote discoveries to meet the needs of the Nation.
Directorate for Mathematical & Physical Sciences
Office of Multidisciplinary Activities
NSF MISSION
To promote the progress of science; to advance the national health, osperity, and welfare; to secure the national defense (NSF Act of 1950)
NSF VISION
Advancing discovery, innovation, and education beyond the frontiers of current knowledge, and empowering future generations in
science and engineering.
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Dear Reader:
We are pleased to tell you about the Mathematical and Physical Sciences Directorate (MPS) of the National Science Foundation. MPS supports fundamental advances in astronomy, chemistry, materials research, mathematical sciences, and physics. These activities both excite our imaginations and change our lives, providing a foundation for innovation that advances economic growth, public health, and national security.
With an FY 2012 budget exceeding $1.3 billion, MPS research spans the range of distances and times accessible to human investigation--lengths ranging from less than the diameter of an atom to the size of galaxies, and times ranging from those for the very fastest chemical reactions to those for the evolution of the universe. MPS research develops new mathematical structures and explores the behavior of the fundamental constituents of matter. The new insights that come from this research bear on exploration of complex biological systems, sustainability and the environment, and human and social dynamics. Just a few examples of the practical consequences of research in mathematical and physical sciences are the invention of medical imaging technology; the development of ultrasensitive biological and chemical detectors; advances in alternate fuel technologies; and transformations in electronics, photonics, and optics.
Research in the mathematical and physical sciences is the bedrock of technological innovation. In the next few years, MPS-funded research will advance the nation’s investments in sustainable energy and food supplies, cyberinfrastructure, and the rapid incorporation of newly invented materials into practical devices at low cost. We will support research that connects the life sciences to the mathematical and physical sciences; that enhances the nation’s wireless communications infrastructure; and that reveals the very nature of matter, space, time and the physical laws governing the universe.
We hope this brochure gives you a flavor of the research we support at universities and laboratories throughout the nation, and we invite you to learn more about us on our web site at www.nsf.gov/MPS.
Best regards,
F. Fleming Crim
Assistant Director Directorate for Mathematical and Physical Sciences
4
Directorate for Mathematical & Physical Sciences
HUMAN RESOURCES FY 2012Distribution of people supported by MPS.
35%
10% 7%
27%
21% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
35%
10%7%
27%
21% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
BUDGET IN ACTUAL AND CONSTANT FY 2000 DOLLARSConstant dollars show the purchasing power of the MPS budget.
$1,200
$1,400
$1,600
$200
$0
$600
$400
$800
$1,000
$1,800
$2,000Millions
Fiscal Year00 01 02 03 04 05 06 07 08 09 10 11 12
Constant FY 2000 Dollars ActualARRA*
* ARRA - American Recovery and Reinvestment Act of FY 2009.
Data provided from FY 2000 to 2012 NSF Budget Requests to Congress, www.nsf.gov/about/budget
5
FUNDING RATES AND NUMBER OF ACTIONS
* FY 2009 funding rate includes awards made with ARRA funds.
Note: The funding reflects the average for the Directorate and may not represent funding rates in individual Divisions or programs
Graph shows number of proposals submitted and awarded Research Grants (as defined by NSF) and resultant funding rates. Funding rate is defined as the percentage of new or renewal proposals awarded funding.
37%
32% 33%31%
28% 27% 28%
36%
0%
15%
20%
5%
10%
25%
35%
30%
40%
Funding Rate %% FundedProposals Received Awarded
Number of Actions
0
1,000
2,000
3,000
4,000
5,000
6,000
7,000
8,000
9,000
Fiscal Year04 05 06 07 08 09* 10 11 1200 01 02 03
30%27%
26% 25% 25%
MPS
6
Division of Astronomical Sciences (AST)
Mission
The mission of the Division of Astronomical Sciences (AST) is to support forefront research in ground-based astronomy; to help ensure the scientific excellence of the U.S. astronomical community; to provide access to world-class research facilities through merit review; to support the development of new instrumentation and next-generation facilities; and to encourage broad understanding of the astronomical sciences by a diverse population of scientists, policy makers, educators, and the public at large.
The Division supports research in all areas of astronomy and astrophysics as well as related multidisciplinary studies. Because of the scale of modern astronomical research, the Division engages in numerous interagency and international collaborations. Areas of emphasis and the priorities of specific programs are guided by community recommendations, which have been developed and transmitted by National Research Council decadal surveys and by federal advisory committees.
Astronomical Facilities
The Division invested 57% of its FY 2012 appropriation in the management and operation of ground-based astronomical facilities. Through the national observatories and international partnerships, the Division provides support for a system of multi-aperture research-class telescopes that enable transformational capabilities in both radio and optical/infrared astronomy. In 2012, the upgraded Karl G. Jansky Very Large Array was completed, and in 2013, the international Atacama Large Millimeter/submillimeter Array was inaugurated. During FY 2013, ground was also broken on the Advanced Technology Solar Telescope, a part of the National Solar Observatory to be constructed on Haleakalā Mountain in Hawaii. Furthermore, technological advances in a number of key areas of telescope construction and design, including sophisticated adaptive optics technology at the Gemini Observatory and the Advanced Technology Solar Telescope, allow these and other national facilities to operate at the forefront of ground-based capabilities.
Contact Information
Dr. James S. Ulvestad Division Director
Dr. Patricia Knezek Deputy Division Director
National Science FoundationDivision of Astronomical Sciences 4201 Wilson Boulevard Room 1045 Arlington, VA 22230
PHONE: (703) 292-8820 FAX: (703) 292-9034 WEB: www.nsf.gov/AST
The Atacama Large Millimeter/submillimeter Array (ALMA) was inaugurated and will go into full operation in 2013. ALMA will function as the most capable imaging radio telescope ever built. This image shows a subset of ALMA’s 66 antennas in operation at 5000 meters elevation in the Chilean Andes, with the plane of the Milky Way Galaxy crossing the sky in the background.
Credit: NRAO/AUI, NSF, ESO, and NAOJ.
7
ASTu Astronomy and Astrophysics Research
Grants (AAG)u Enhancing Access to the Radio Spectrum
(EARS)u Faculty Early Career Development
Program (CAREER)u NSF Astronomy and Astrophysics
Postdoctoral Fellowships (AAPF)
u Partnerships in Astronomy and Astrophysics Research and Education (PAARE)
u Research Experiences for Undergraduates (REU)
u Research in Undergraduate Institutions (RUI)
u Theoretical and Computational Astrophysics Networks (TCAN)
AST represents the interests of NSF and the scientific community in protecting access to portions of the electromagnetic spectrum that are needed for research purposes. The sensitivity of telescopes can be compromised by electromagnetic interference from sources such as airborne and satellite radio transmissions and light pollution. ESM personnel protect scientific capabilities by participating in the establishment of regulations, operating procedures, and technical standards related to government, private sector, and international uses of the spectrum. The ESM unit also is the home of the research program Enhancing Access to the Radio Spectrum (EARS), which seeks to optimize the use of the radio spectrum for a variety of societal needs.
ELECTROMAGNETIC SPECTRUM MANAGEMENT (ESM)
INDIVIDUAL INVESTIGATOR PROGRAMS
u Arecibo Observatoryu Atacama Large Millimeter/submillimeter Array (ALMA)u Gemini Observatoryu National Optical Astronomy Observatoryu National Radio Astronomy Observatoryu National Solar Observatory
LARGE FACILITIES
PHONE: (703) 292-8820 FAX: (703) 292-9034 WEB: www.nsf.gov/AST
Optical image of the galaxy NGC 1365 in the Fornax Cluster, taken by the Dark Energy Camera (funded by the Department of Energy) installed on the Blanco 4-meter telescope of the National Optical Astronomy Observatory. The image covers only a very small portion of the field of view of the camera. The Dark Energy Survey, using this telescope/camera combination, begins in 2013 and will continue for a five-year primary mission.
Credit: Dark Energy Survey Collaboration
u Advanced Technologies and Instrumentation (ATI)u Major Research Instrumentation (MRI)
ASTRONOMICAL INSTRUMENTATION PROGRAMS
8
HUMAN RESOURCES FY 2012Distribution of people supported by AST.
36%
28% 6%
14%
16% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
36%
28% 6%
14%
16% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
BUDGET IN ACTUAL AND CONSTANT FY 2000 DOLLARSConstant dollars show the purchasing power of the AST budget.
* ARRA - American Recovery and Reinvestment Act of FY 2009.
Data provided from FY 2000 to 2012 NSF Budget Requests to Congress, www.nsf.gov/about/budget
$0
$50
$100
$150
$200
$250
$300
$350 Millions
Constant FY 2000 Dollars ActualARRA*
Fiscal Year00 01 02 03 04 05 06 07 08 09 10 11 12
Division of Astronomical Sciences (AST)
9
FUNDING RATES AND NUMBER OF ACTIONS
* FY 2009 funding rate includes awards made with ARRA funds.
Note: The funding reflects the average for AST and may not represent funding rates in individual programs
17%20%
18%
49%
22%24%26%27%
29%
35%36%32%34%
0%
10%
20%
30%
50%
40%
60%
Funding Rate %
Fiscal Year
Number of Actions % FundedProposals Received Awarded
0
100
200
300
400
500
600
700
800
900
1,000
04 05 06 07 08 09* 10 11 1200 01 02 03
Graph shows number of proposals submitted and awarded Research Grants (as defined by NSF) and resultant funding rates. Funding rate is defined as the percentage of new or renewal proposals awarded funding.
MODES OF SUPPORT FY 2012
57%
18%
13%
6% 6%
Individual Investigators& Small Teams
Instrumentation Programs &University Radio Observatories
Education & WorkforceDevelopment Programs
Facilities
Special Projects
57%
18%
13%
6% 6%
Individual Investigators& Small Teams
Instrumentation Programs &University Radio Observatories
Education & WorkforceDevelopment Programs
Facilities
Special Projects
AST
10
Mission
The mission of the NSF Division of Chemistry (CHE) is to support innovative research in chemical sciences, integrated with education, through strategic investment in developing a globally engaged U.S. chemistry workforce reflecting the diversity of America.
Funding Modalities
Research projects (individual investigators and small teams) remain the dominant funding modality in CHE, accounting for 84% of the Division’s budget in FY 2012. CHE also invests in research centers (6%), shared instrumentation (6%), and education (4%).
Workforce Development and Broadening Participation
CHE supports roughly 75 Research Experiences for Undergraduates (REU) sites, which represent many different models of undergraduate research. An exciting part of the portfolio is the international REU Sites, where U.S. undergraduate students have the opportunity to live and conduct research abroad for eight to ten weeks. CHE supports international (iREU) sites in Europe and Asia.
Chemistry and the Global Community
CHE has developed effective partnerships with select funding agencies in other countries that allow joint review and funding of collaborative international research projects. Proposals submitted to the “International Collaboration in Chemistry” program enable graduate students, postdocs, and undergraduate students to participate in extended research visits to their collaborators’ laboratories abroad. The program also encourages the development and use of cyber infrastructure to enhance the partnerships supported.
Contact Information
Dr. Tanja Pietraß Division Director (Acting)
Dr. Linda Sapochak Deputy Division Director (Acting)
National Science FoundationDivision of Chemistry 4201 Wilson Boulevard Room 1055 Arlington, VA 22230
PHONE: (703) 292-8840 FAX: (703) 292-9037 WEB: www.nsf.gov/CHE
A silicon photovoltaic cell (the artificial leaf). The photovoltaic cell can capture the energy of sunlight and use that energy to do a chemical reaction - the splitting of water into hydrogen (a fuel) and oxygen.
Credit: Dan Nocera, MIT
Division of Chemistry (CHE)
11
PHONE: (703) 292-8840 FAX: (703) 292-9037 WEB: www.nsf.gov/CHE
u Chemical Catalysisu Chemical Measurement and Imagingu Chemical Structure, Dynamics and
Mechanismsu Chemical Synthesisu Chemistry of Life Processes
u Chemical Theory, Models and Computational Methods
u Environmental Chemical Sciencesu Macromolecular, Supramolecular
and Nanochemistry
INDIVIDUAL INVESTIGATOR PROGRAMS
LOWER IMAGE: Catalytic cycle for the conversion of non-food biomass (switch grass, corn stover, sugar cane bagasse, poplar, etc.) to the most important synthetic polymer PE, used for products ranging from joint implants to shopping bags.
The Centers for Chemical Innovation (CCI) Program supports centers focused on major, long-term fundamental chemical research challenges. CCIs that address these challenges will produce transformative research, lead to innovation, and attract broad scientific and public interest.
One of the Division’s priorities is the NSF-wide program in Sustainable Chemistry, Engineering and Materials (SusChEM). Proposals are supported by all modalities including the individual investigator programs. The division will support basic research in SusChEM to:
u Discover new chemistry that will replace rare, expensive and/or toxic chemicals with earth-abundant, inexpensive and benign chemicals.
u Discover new chemistry to economically recycle chemicals that can not be replaced, such as phosphorus and the rare earth elements.
u Discover new chemistry to convert non-petroleum based sources of organics to feedstock chemicals.
u Discover new environmentally friendly chemical reactions and processes that require less energy, water, and organic solvents than current practice.
INTEGRATIVE CHEMISTRY ACTIVITIES• Centers for Chemical Innovation
• Chemical Research Instrumentation and Facilities
• Research Experiences for Undergraduates
UPPER IMAGE: (#1) Illustration of an energy-saving process for the conversion of a trimethylsulfoxonium iodide salt to polymethylene in water. (#2) Mechanism for the polymer production
#1
#2
Credit: Jun Luo; Kenneth J. Shea, University of California, Irvine
Credit: Jun Luo; Kenneth J. Shea, University of California, Irvine
CHE
12
HUMAN RESOURCES FY 2012Distribution of people supported by CHE.
BUDGET IN ACTUAL AND CONSTANT FY 2000 DOLLARSConstant dollars show the purchasing power of the CHE budget.
* ARRA - American Recovery and Reinvestment Act of FY 2009.
Data provided from FY 2000 to 2012 NSF Budget Requests to Congress, www.nsf.gov/about/budget
$0
$50
$100
$150
$200
$250
$300
$350 Millions
Constant FY 2000 Dollars ActualARRA*
Fiscal Year00 01 02 03 04 05 06 07 08 09 10 11 12
35%
10% 7%
27%
21% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
33%
Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
27%
31% 7%
Division of Chemistry (CHE)
13
FUNDING RATES AND NUMBER OF ACTIONS
* FY 2009 funding rate includes awards made with ARRA funds.
Note: The funding reflects the average for CHE and may not represent funding rates in individual programs
0%
10%
5%
15%
20%
30%
25%
35%
Funding Rate %
Fiscal Year
Number of Actions % FundedProposals Received Awarded
0
500
1,000
1,500
2,000
2,500
04 05 06 07 08 09* 10 11 1200 01 02 03
21%21%23%
32%
25%23%
27%
30%30%30%
32%
25%27%
Graph shows number of proposals submitted and awarded Research Grants (as defined by NSF) and resultant funding rates. Funding rate is defined as the percentage of new or renewal proposals awarded funding.
MODES OF SUPPORT FY 2012
84%
4% 6% 6%
Centers
Shared Instrumentation
Education & Workforce
Individual Investigators &Small Teams
84%
4% 6% 6%
Centers
Shared Instrumentation
Education & Workforce
Individual Investigators &Small Teams
CHE
14
Division of Materials Research (DMR)
Mission
The mission of the Division of Materials Research (DMR) is to make new discoveries about the behavior of matter and materials and new knowledge about materials phenomena; to address fundamental materials questions that often transcend traditional scientific and engineering disciplines and may lead to new technologies; to prepare the next generation of materials researchers; to develop and support the instruments and facilities that are crucial to advance the field; and to share the excitement and significance of materials science with the general public.
DMR supports experimental and theoretical research, their interplay with each other and with data, over a broad range of subfields. These include condensed matter and materials physics, solid state and materials chemistry, electronic and photonic materials, metals and metallic nano structures, polymers, ceramics,
and biomaterials. Funding modes range from awards to individual investigators, to small groups to centers, instrumentation, and major facilities.
Workforce Development and Broadening Participation
DMR strives to broaden the participation of women and underrepresented minority groups in science and engineering at all academic levels. One outcome of this vision is the Partnership for Research and Education in Materials (PREM) program, which develops and supports long-term partnerships between academic institutions serving underrepresented groups and DMR centers and facilities. PREM was started in 2004 and currently supports 14 awards.
Contact Information
Dr. Mary Galvin Division Director
Dr. Janice Hicks Deputy Division Director
National Science FoundationDivision of Materials Research 4201 Wilson Boulevard Room 1065 Arlington, VA 22230
PHONE: (703) 292-8810 FAX: (703) 292-9036 WEB: www.nsf.gov/DMR
Using a new technique called “atom probe tomography,” researchers at Northwestern University observed that chitons, “rock-munching” marine mollusks, have teeth that are four times harder than human teeth that are self-sharpening. Structural studies revealed that these teeth are composites of nanocrystalline magnetic iron oxide with organic fibers. Understanding the structures of these interesting materials will allow researchers to design new synthetic materials for unprecedented hardness and function.
Credit: Derk Joester
15
DMRu Biomaterialsu Ceramicsu Computational and Data-Driven
Materials Researchu Condensed Matter and Materials Theory
u Condensed Matter Physicsu Electronic and Photonic Materialsu Metallic Materials and Nanostructuresu Polymersu Solid State and Materials Chemistry
PROGRAMS FOR INDIVIDUAL INVESTIGATORS AND GROUPS
PHONE: (703) 292-8810 FAX: (703) 292-9036 WEB: www.nsf.gov/DMR
Researchers at the University of California–Santa Barbara designed a material for its magnetic properties starting from constituent atoms in a successful example of materials by design. The image shows how the atoms of europium (Eu), barium (Ba), oxygen (O), and titanium (Ti), are arranged on a crystalline lattice of the material.
Credit: Nicola Spaldin
Materials Research Science and Engineering Centers (MRSECs): MRSECs address fundamental materials research whose scope and complexity require the advantages of scale and interdisciplinarity provided by a center. The MRSEC program currently supports 27 centers. For more information, visit www.mrsec.org
Partnerships in Research and Education in Materials (PREM)
National FacilitiesDMR supports facilities for neutron scattering, x-rays, high magnetic fields, and nanofabrication.
Office of Special ProgramsThe Materials World Network (MWN): The MWN, initiated and supported by DMR in partnership with over fifty research funding organizations worldwide, engages global resources for the advancement of materials research and education through collaborative projects.
Research Experience for Undergraduates (REU) and Teachers (RET)
Designing Materials to Revolutionize and Engineer our Future (DMREF)DMR participates in the DMREF activity, which encourages proposals that integrate experimental, theoretical and data-driven efforts and that iterate these steps to achieve more rapid materials discovery.
Sustainable Chemistry, Engineering and Materials (SusChEM) DMR also participates in the SusChEM activity for research that extends natural resources, replaces materials for a safer and more secure future, and designs materials for zero waste.
CROSSCUTTING DMR PROGRAMS
16
HUMAN RESOURCES FY 2012Distribution of people supported by DMR.
18% 30%
35%
8% 9%
Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
18% 30%
35%
8% 9%
Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
BUDGET IN ACTUAL AND CONSTANT FY 2000 DOLLARSConstant dollars show the purchasing power of the DMR budget.
* ARRA - American Recovery and Reinvestment Act of FY 2009.
Data provided from FY 2000 to 2012 NSF Budget Requests to Congress, www.nsf.gov/about/budget
$250
$300
$350
$50
$0
$100
$150
$200
$400
$450
Millions
Constant FY 2000 Dollars ActualARRA*
Fiscal Year00 01 02 03 04 05 06 07 08 09 10 11 12
Division of Materials Research (DMR)
17
FUNDING RATES AND NUMBER OF ACTIONS
* FY 2009 funding rate includes awards made with ARRA funds.
Note: The funding reflects the average for DMR and may not represent funding rates in individual programs
23%
19%
26%
29%
21%22%20%
22%23%
32%
25%
29%
35%
0%
15%
10%
5%
20%
25%
35%
30%
40%
Funding Rate %
Fiscal Year
Number of Actions
% FundedProposals Received Awarded
0
800
600
400
200
1,000
1,200
1,600
1,400
1,800
04 05 06 07 08 09* 10 11 1200 01 02 03
Graph shows number of proposals submitted and awarded Research Grants (as defined by NSF) and resultant funding rates. Funding rate is defined as the percentage of new or renewal proposals awarded funding.
MODES OF SUPPORT FY 2012
56%
5%
20%
19% Centers
Facilities & Instrumentation
Education & Workforce
Individual Investigators &Small Teams
56%
5%
20%
19% Centers
Facilities & Instrumentation
Education & Workforce
Individual Investigators &Small Teams
DMR
18
Division of Mathematical Sciences (DMS)
Mission
The mission of the NSF Division of Mathematical Sciences (DMS) is to support research at the frontiers of discovery in mathematical sciences and to support education in the mathematical sciences through research involvement of trainees. DMS is responsible for programs with a total annual budget of over $230 million. These programs support research and education that expand the knowledge base of the mathematical and statistical sciences through awards to individual investigators and small groups, workforce training grants, and a portfolio of national mathematical sciences research institutes.
Discovery, Connections, Community
The influence of mathematical sciences on our daily lives is fundamental and pervasive. For example, every secure commercial transaction on the Internet is an application of research in number theory and algebraic geometry. Additionally, improvements in weather prediction, search engines, and industrial design processes rest on advances in algorithms and computational mathematics. DMS invests in discovery in mathematics and statistics; promotes interdisciplinary connections across fields of science, engineering, and technology; and cultivates a diverse and capable community of researchers, students, and professionals.
The Division’s top investment priorities – discovery, connections, and community – are essential components of the innovation engine that drives the nation’s economy in the 21st Century.
New Initiatives
DMS continues to develop interdisciplinary activities that reflect national priorities. Successful multi-agency programs such as Algorithms for Threat Detection and the Joint DMS & National Institute of General Medical Sciences Activity in Mathematical Biology are continuing, and newer DMS activities such as the Computational and Data-Enabled Science and Engineering in Mathematical and Statistical Sciences program are attracting broad interest from the mathematical sciences community. The DMS Workforce Program in the Mathematical Sciences offers competitions such as Expeditions in Training, Research, and Education for Mathematics and Statistics through Quantitative Explorations of Data, whose goal is to increase the number of well-prepared students who pursue careers in the mathematical sciences and in other NSF-supported disciplines. Additionally, NSF-wide programs in Cyberinfrastructure Framework for the 21st Century; Materials Genome Initiative; and Science, Engineering, and Education for Sustainability are providing new opportunities for engagement of the mathematical sciences community.
Contact Information
Dr. Sastry Pantula Division Director
Dr. Henry Warchall Deputy Division Director
National Science FoundationDivision of Mathematical Sciences 4201 Wilson Boulevard Room 1025 Arlington, VA 22230
PHONE: (703) 292-8870 FAX: (703) 292-9032 WEB: www.nsf.gov/DMS
19
DMS
The Mathematics Research Communities (MRC) Program, run by the American Mathematical Society and supported by DMS, helps cement new research collaborations through targeted summer conferences, Special Sessions at the Joint Mathematics Meetings, private online discussion networks, and mentoring by senior mathematicians. Ongoing collaborations of MRC alumni include small groups of MRC participants working together, individual participants working with senior mentors from the MRC program, and groups of MRC participants and organizers getting together for workshops to share ideas and explore new avenues. www.ams.org/programs/research-communities/mrc
CORE PROGRAMS
The Mathematical Sciences Research Institutes program supports a portfolio of projects that advances research in the mathematical sciences, increases the impact of the mathematical sciences in other disciplines, enables the mathematical sciences to respond to national needs, and expands the talent base engaged in mathematical and statistical research in the United States.
u Algorithms for Threat Detectionu Computational and Data-Enabled Science and
Engineering in Mathematical and Statistical Sciencesu Focused Research Groups in the Mathematical Sciencesu Infrastructureu Joint DMS/NIGMS Initiative in Mathematical Biologyu Research Networks in the Mathematical Sciencesu Workforce Program in the Mathematical Sciences
SPECIAL DMS PROGRAMS
PHONE: (703) 292-8870 FAX: (703) 292-9032 WEB: www.nsf.gov/DMS
u Algebra and Number Theory
u Analysis
u Applied Mathematics
u Combinatorics
u Computational Mathematics
u Foundations
u Geometric Analysis
u Mathematical Biology
u Probability
u Statistics
u Topology
MATHEMATICS RESEARCH COMMUNITIES
MRC participants working on a project at the 2008 MRC conference on Scientific Computing and Advanced Computation.
Credit: Ellen Maycock and David Eisenbud
MRC participants and organizer Claudia Polini working on a project at the 2010 MRC Conference in Commutative Algebra.
Credit: Ellen Maycock and David Eisenbud
ELLIPTIC CURVES: Mathematics is the study of patterns and relationships. Mathematical concepts are used to describe and understand the world, and abstract mathematical reasoning surprisingly often underlies human progress. The curve pictured here is an example of a mathematical construct in algebra, geometry, and number theory. Such elliptic curves play a role in the proof of Fermat’s last theorem, and they underlie some modern public-key cryptosystems used for secure Internet commerce. The figure illustrates geometrically a fundamental algebraic computation central to the elliptic curve cryptography scheme endorsed by the U.S. National Security Agency.
Credit: Karl Rubin, University of California, Irvine
20
HUMAN RESOURCES FY 2012Distribution of people supported by DMS.
Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads 28%
45%
20%
5%
BUDGET IN ACTUAL AND CONSTANT FY 2000 DOLLARSConstant dollars show the purchasing power of the DMS budget.
* ARRA - American Recovery and Reinvestment Act of FY 2009.
Data provided from FY 2000 to 2012 NSF Budget Requests to Congress, www.nsf.gov/about/budget
$0
$50
$100
$150
$200
$250
$300
$350 Millions
Constant FY 2000 Dollars ActualARRA*
Fiscal Year00 01 02 03 04 05 06 07 08 09 10 11 12
Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads 28%
45%
20%
5%
Division of Mathematical Sciences (DMS)
21
FUNDING RATES AND NUMBER OF ACTIONS
* FY 2009 funding rate includes awards made with ARRA funds.
Note: The funding reflects the average for DMS and may not represent funding rates in individual programs
30%29%31%
35%
30%32%
29%26%
33%36%
38%37%
30%
0%
15%
10%
5%
20%
25%
35%
30%
40%
Funding Rate %
Fiscal Year
Number of Actions % FundedProposals Received Awarded
0
500
1,000
1,500
2,500
2,000
3,000
04 05 06 07 08 09* 10 11 1200 01 02 03
Graph shows number of proposals submitted and awarded Research Grants (as defined by NSF) and resultant funding rates. Funding rate is defined as the percentage of new or renewal proposals awarded funding.
MODES OF SUPPORT FY 2012
74%
16%
10%
Education & Workforce
Institutes
Individual Investigators &Small Teams
74%
16%
10%
Education & Workforce
Institutes
Individual Investigators &Small Teams
DMS
22
Mission
The mission of the Division of Physics (PHY) is to support fundamental research across the intellectual frontiers of physics, to support research that has broader impacts on other fields of science and on the health, economic strength, and defense of society, to enhance education at all levels and share the excitement of science with the public through integration of education and research, and to steward the physics community so as to maintain the intellectual capital essential for future advances.
Physics research probes the properties of matter at its most fundamental level, the interactions between particles, and the organization of constituents and symmetry principles that lead to the rich structure and phenomena that we observe in the world around us. Physics seeks a deep understanding of processes that led to the formation of the
cosmos, to the structure of matter at the very shortest distance scales where quantum effects dominate, and to the structure of atomic and molecular systems that shape and control the everyday world of chemistry and biological systems.
Workforce Development and Broadening Participation
The Physics Division strongly supports workforce development and broadening participation at all levels, from outreach efforts in large facilities and centers, to a variety of opportunities for undergraduates through the REU program, to large-scale projects such as QuarkNet (an outreach program that connects cutting-edge physics to the high school classroom), to individual PI awards. Students involved in these projects gain skills and knowledge to become members of the nationally critical high tech workforce.
Contact Information
Dr. C. Denise Caldwell Division Director
Dr. Bradley D. Keister Deputy Division Director (Acting)
National Science Foundation Division of Physics4201 Wilson Boulevard Room 1015 Arlington, VA 22230
PHONE: (703) 292-8890 FAX: (703) 292-9078 WEB: www.nsf.gov/PHY
u Atomic, Molecular, Optical and Plasma Physics
u Physics of Living Systemsu Accelerator Scienceu Elementary Particle Physicsu Gravitational Physics
u Nuclear Physicsu Particle Astrophysicsu Physics at the Information
Frontieru Education and
Interdisciplinary Research
u Theoretical Physics (including Atomic, Molecular, and Optical Physics, Elementary Particle Physics, Nuclear Physics, Cosmology and Astrophysics, and Mathematical Physics)
PROGRAMS FOR INDIVIDUAL INVESTIGATORS AND GROUPS
Division of Physics (PHY)
23
PHONE: (703) 292-8890 FAX: (703) 292-9078 WEB: www.nsf.gov/PHY
Displays of candidate Higgs Boson events from the ATLAS and CMS Experiments at the CERN Large Hadron Collider: (upper) Higgs decay into 4 muons in the ATLAS Detector with muon tracks colored in red; (lower) Higgs decay into a pair of photons in the CMS Detector with photons indicated by dashed yellow lines and green towers.
ATLAS Experiment ©2012 CERN
©2012 CERN, for the benefit of the CMS Collaboration
This program has been established to foster major advances at the intellectual frontiers of physics by providing needed resources, including combinations of talents, skills, disciplines, and/or specialized infrastructure, not usually available to individual investigators or small groups.
The program supports university-based centers and institutes where the collective efforts of a larger group of individuals can enable transformational advances in the most promising research areas. Activities supported through the program are in all sub-fields of physics within the purview of the Division of Physics. Interdisciplinary projects at the interface between these physics areas and other physics sub-fields and disciplines, such as quantum information science, mathematical physics, and condensed matter physics, and emerging areas of physics are also included.
THE PHYSICS FRONTIER CENTERS
u Physics Frontier Centersu National Facilities
u National Supercomputing Cyclotron Laboratory (NSCL)u Laser Interferometer Gravitational Wave
Observatory (LIGO)u Large Hadron Collider (LHC), a joint
NSF-DOE-CERN projectu IceCube Neutrino Observatory u Large Plasma Device (LAPD)
u Research Experience for Undergraduates (REU) and Teachers (RET)
CROSSCUTTING PHYSICS PROGRAMS
The PHY Division participates in numerous international efforts, including large scale facilities such as the LIGO, LHC and IceCube facilities, and large astrophysics detectors such as Borexino, and the Pierre Auger Observatory. In addition, the PHY Division also participates in the Open Science Grid, a distributed shared cyberinfrastructure which provides computing and storage resources for large NSF supported international projects and partners internationally with other grid projects in Europe and releated efforts in South America and Asia.
PHYSICS AND THE GLOBAL COMMUNITY
PHY
24
HUMAN RESOURCES FY2012Distribution of people supported by PHY.
28%
19% 19%
9%
25% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
28%
19% 19%
9%
25% Senior Researchers
Other Professionals
Postdocs
Grad Students
Undergrads
BUDGET IN ACTUAL AND CONSTANT FY 2000 DOLLARSConstant dollars show the purchasing power of the PHY budget.
* ARRA - American Recovery and Reinvestment Act of FY 2009.
Data provided from FY 2000 to 2012 NSF Budget Requests to Congress, www.nsf.gov/about/budget
$200
$250
$300
$0
$50
$100
$150
$350
$400Millions
Constant FY 2000 Dollars ActualARRA*
Fiscal Year00 01 02 03 04 05 06 07 08 09 10 11 12
Division of Physics (PHY)
25
FUNDING RATES AND NUMBER OF ACTIONS
* FY 2009 funding rate includes awards made with ARRA funds.
Note: The funding reflects the average for PHY and may not represent funding rates in individual programs
38%
32%35%
48%
32%
39%
44%
34%38%
46%
39%38%
48%
0%
10%
20%
30%
50%
40%
60%
Funding Rate %
Fiscal Year
Number of Actions % FundedProposals Received Awarded
0
100
200
300
400
500
600
700
800
900
1,000
04 05 06 07 08 09* 10 11 1200 01 02 03
Graph shows number of proposals submitted and awarded Research Grants (as defined by NSF) and resultant funding rates. Funding rate is defined as the percentage of new or renewal proposals awarded funding.
MODES OF SUPPORT FY 2012
Facilities/Instrumentation
Centers
63% 30%
7% Individual Investigators& Small Teams
Facilities/Instrumentation
Centers
63% 30%
7% Individual Investigators& Small Teams
PHY
Contact Information
Dr. Clark Cooper Head of OMA & Senior Advisor for Science
National Science Foundation Office of Multidisciplinary Activities4201 Wilson Boulevard Room 1005 Arlington, VA 22230
PHONE: (703) 292-8800 FAX: (703) 292-9151 WEB: www.nsf.gov/OMA
Proposal Review: MPS maximizes the quality of the proposals it supports through the use of a competitive, merit-based review process. In FY 2012, 94.5% of research funds were allocated to externally reviewed projects.
Committee of Visitors (COV): MPS convenes Committees of Visitors, composed of qualified external evaluators, to review each program periodically. These experts assess the integrity and efficiency of the processes for proposal review. COV reports and relevant Directorate responses are available at www.nsf.gov/
od/oia/activities/cov/covs.jsp.
MPS Advisory Committee (MPSAC): The Mathematical and Physical Sciences Advisory Committee advises MPS on issues such as: the mission, programs, and goals that can best serve the scientific community; promoting quality graduate and undergraduate education in the mathematical and physical sciences; and priority investment areas in MPS-supported research. Minutes from MPSAC meetings are available at www.nsf.gov/mps/advisory.jsp
PHONE: (703) 292-8800 | FAX: (703) 292-9151 | ROOM: 1005N | www.nsf.gov/MPS
Mathematical Physical Sciences
Director ate For
&
OMA seeds crosscutting research in areas of strategic emphasis for MPS as well as areas that might develop into strategic importance; facilitates, partnerships with other agencies, national laboratories, industries, state and local governments, and international organizations; and supports innovative experiments in education and broadening participation. The purpose of OMA investments is to initiate, but not sustain indefinitely, these activities.
OMA does not accept external proposals. Rather it encourages submission from MPS Divisions of initiatives and projects that are multi-investigator, multi-disciplinary, and strategic to MPS, as well as innovative projects incorporating education and broadening participation that contribute to a diverse, technical workforce.
OFFICE OF MULTIDISCIPLINARY ACTIVITIES (OMA)
MPS
PHONE: (703) 292-8800 FAX: (703) 292-9151 WEB: www.nsf.gov/OMA
MPS StaffDr. F. Fleming Crim Assistant Director
Dr. Celeste M. Rohlfing Deputy Assistant Director
Mr. Caleb Autrey Science Assistant
Ms. Zita R. Barnett Directorate Administrative Coordinator
Mr. Keith Bennett Systems Analyst
Dr. Clark Cooper Senior Science Advisor/Head, OMA
Ms. Abby Deift Science Assistant
Ms. Lynnea Garrett Administrative Assistant (Student Trainee)
Dr. Susan G. Hamm Directorate Operations Officer
Ms. Angela Harris Operations Specialist
Dr. G. Wayne Van Citters Senior Advisor, Facilities & Planning Mgt.
Mathematical and Physical Sciences Advisory Committee (MPSAC) Membership List
Term Expires 9/30/2013
Dr. Paul Butler Carnegie Institute of Washington
Dr. Eric Cornell NIST/University of Colorado
Dr. Naomi Halas Rice University
Dr. Dennis Matthews University of California, Davis
Dr. Michael Norman University of California, San Diego
Dr. Eugenia Paulus North Hennepin Community College
Dr. Esther Takeuchi University of New York, Buffalo
Term Expires 9/30/2014
Dr. Emery Brown Massachusetts Institute of Technology
Dr. James Berger Duke University
Dr. Daniela Bortoletto Purdue University
Dr. Francis DiSalvo Cornell University
Dr. Bruce Elmegreen IBM
Dr. Barbara Finlayson-Pitts University of California, Irvine
Dr. Irene Fonesca Carnegie Mellon University
Dr. Elizabeth Lada University of Florida
Dr. Else Reichmanis Georgia Institute of Technology
Dr. Geoffrey West Santa Fe Institute
Term Expires 9/30/2015
Dr. Emily Carter Princeton University
Dr. George Crabtree Argonne National Laboratory
Dr. Juan de Pablo University of Chicago
Dr. Juan Meza University of California, Merced
www.nsf.gov/MPS
Division of Astronomical Sciences (AST)www.nsf.gov/AST
Division of Chemistry (CHE)www.nsf.gov/CHE
Division of Materials Research (DMR)www.nsf.gov/DMR
Division of Mathematical Sciences (DMS)www.nsf.gov/DMS
Division of Physics (PHY)www.nsf.gov/PHY
Office of Multidisciplinary Activities (OMA)www.nsf.gov/OMA
NSF 13-097
Mathematical Physical Sciences
Director ate For
&